Pathogenesis of Cervical Myelopathy in Chronic Cervical Cord Compression Model of Rat

Pathogenesis of Cervical Myelopathy in Chronic Cervical Cord Compression Model of Rat Shigeru Kobayashi,MD,PhD 1, Masafumi Kubota, PT 1, Hisao Iwamoto, MD,PhD 2, Riya Kosaka,MD,PhD 3, Katsuhiko Hayakawa,MD,PhD 4 1 Department of Orthopaedic and Rehabilitation Medicine, University of Fukui, Fukui, Japan. 2 Department of Orthopaedic Surgery, Iwamoto Orthopaedic Clinic, Osaka, Japan 3 Department of Orthopaedic Surgery, Hirakata City Hospital, Osaka, Japan. 4 Department of Orthopaedic Surgery, Aiko Orthopaedic Clinic, Osaka, Japan Financial Disclosure: None

BACKGROUND In previous studies, Various methods have been tried to induce chronic cord compression. Compression methods Authors Compression course Stenosis Invasion in the spinal canal Screw Epidural tumor Expanding sheet Shinomiya et al., 1992 1) More than 6 months Almost 50% + Hoshino et al., (1 mm / week) 1999 2) 70% + Manabe et al., 1989 3) 13-18 days? - Kim et al., 2004 4) 24 hours 17 weeks 12% + Twy (tip-toe walking Yoshimura) mouse Yamazaki M., et al.,1991 5) 1-6 month 70% - Various methods have been undertaken to induce spinal cord compression. These include transplantation of tumor cells, placement of screws with gradual tightening, implantation of an expanding sheet, a combination of vascular ligation plus screw compression, and the tiptoe-walking Yoshimura (twy/twy) mouse. These models had various difficult problems; the time course of these tumor models was too rapid, epidural tissues were injured during the direct implantation of the sheet or screws placement, and the compression site of twymouse could not select without C1-C2 vertebral level.

C4 3 weeks old rat BW.: 50g [Hypothesis] Cervical development of rat 2mm APD of spinal canal: 1.8 times. APD of vertebral body: 1.9 times (APD= Anteroposterior diameter ) 1 year old rat BW.: 800g If surroundings of cervical spine are concluded with the string at 3 weeks old, spinal canal could not expand any more and the vertebral body could expand during development. After 1 year, the spinal canal would be locally narrowed. PURPOSE To produce a new model of chronic cervical cord compression satisfying following appropriate conditions, and to evaluate motor and sensory functions, MR image and histopathological examination. C4 2mm An appropriate model for the pathophysiology of chronic cord compression should be exhibit a latency period after induction of compression with insidious onset of neurological dysfunctions, followed by a phase of progressive disturbance.

METHODS 3 weeks old SD rat: Control rat: N=10 Model rat: N=10 1 year later C3 C5 C3 C5 PE line + plastic plate Plastic plate Fastening 3 laps around C4 using polyethylene (PE) line and plastic plate Examination: <After 3 month, 6 month, 1 year> Behavioral assessment The Basso, Beattie, and Bresnahan (BBB) scale Treadmill test The maximum treadmill speed. After warming-up in 5 m/min for 1 minute, the speed was increased 1m/min by 5 seconds. Sensory assessment von Frey filaments 100g hair was applied until buckling for 3 sec, 10 times. Recorded the number of times of the escape response. ICC: 0.743 (normal rat, n=5)

Radiological assessment Measurement of antero-posterior distance (APD) of spinal canal <Burrows et al., 1963> MR imaging after 1 year Transverse area of spinal cord <Axial T1-w MR imaging> C4 Histological Study (Motoneurons count after 1 year) Fixation:4%-paraformaldehyde Decarcification: EDTA 2Na 2H2O C4 5mm Transverse area: 12.3 mm 2 Cervical cord (C4-5) Signal-difference-to-noise ratios (SDNR) <Sagittal T2-w MR imaging> 3mm 5μm 60 slices Motoneurons was counted a slice per ten. Nissl stain Normal ventral neuron 20mm SDNRs = SI(ROI) SI(surrounding) Noise(background) SI = Signal Intensities 10µm

BBB scale Maximum treadmill speed (m/min) Behavioral assessment RESULTS The Basso, Beattie, and Bresnahan (BBB) scale 30 20 50 40 30 Treadmill test 10 0 Production (3 weeks old) 3 6 12 months :Mann-Whitney U- : CCS model rat test; p<0.05 BBB scale of CCS model (17.3±1.6 points) rat was lower than control rat (20.8±0.4 points) after 12 months; however there were no differences between each group until 6 months after surgery. 120 100 (%) 80 60 40 20 0 : Control rat, Production (3 weeks old) <Fore-limb> 3 6 12 months 20 10 Sensory assessment (%) 120 100 80 60 40 20 0 Production (3 weeks old) Control rat CCS model rat 3 6 12 months The maximum treadmill speed of CCS model rat was lower than control rat after 1 year. :unpaired t-test; p<0.05 0 Production (3 weeks old) <Hind-limb> 3 6 12 In the von Frey filament test, the response frequency of CCS model had no differences between control rats until 6 month after surgery, but the decreasing response frequency of CCS model appeared after 12 months. : Control rat, : CCS model rat months

A-P diameter at C4 (mm) % of control Radiological assessment 4 3 2 (%) 110 100 90 80 70 6 months Production (3 weeks old) 3 months 1 Control rat CCS model rat 60 50 12 months 0 Production 3 months (3 weeks old) 6 months 1 year 40 C2 C3 C4 C5 C6 Cervical Segment The mean A-P diameter of spinal canal at C4 compression level of CCS model was progressively narrowed, and after 12 months, which was about 65% of control rat.

Transverse area at C4 (mm 2 ) Control rat MR imaging study Transverse area of spinal cord Model rat C4 C4 Compression T1-w Control rat Model rat :unpaired t-test: p<0.05 At 12 months after surgery, compression of the spinal cord was evident with flattening of the cross-section view in CCS model rat. The transverse area of the spinal cord was 10.57±1.9mm 2 in the control rat and 7.98±1.7mm 2 in CCS model rat.

SDNRs at C4 High intensity area in the cervical cord [Signal-difference-to-noise ratios (SDNR)] Control rat Model rat 40.0 35.0 30.0 25.0 20.0 15.0 10.0 T2-w 5.0 0.0 Control rat Model rat :unpaired t-test: p<0.05 The SDNR of CCS model rat (31.4±11.6) was significant higher than normal rat (20.4±5.5), and a high-intensity area in T2-weighted MRI of spinal cord was observed in the CCS model rat (arrow).

Control rat Histological Study Model rat Number of motoneurons at C4 (Number / 60 slices) (cells) 1000 800 600 400 200 0 Control rat Model rat :unpaired t-test: p<0.05 In the CCS model rat, the spinal cord was compressed along the whole circumference, and the neurons were flatter, smaller, and decreased in number of motoneurons in the gray matter.

DISCUSSION Skeletal maturity Rat: 2 months of age Human: 13-16 years old <Adler M. et al, Vet Pathol, 1983> 6) neurological dysfunction(+) 1 year old (rat) = 80 years old (human)? Production of model CORD COMPRESSION Induction of compression 6 months old (rat) = 40 years old (human) time We suggested that our model might reproduce any conditions of chronic spinal cord compression in human, because induction of canal stenosis was about 40 s and neurological dysfunctions were insidious onset about 80 s from skeletal maturity relationships between rat and human.

Human 65y.o. Male OPLL Comparison of our chronic cervical compression model and cervical canal stenosis as seen human Rat model High-intensity in the cervical cord (+) Decreased of transverse area Neurons were flatted and small. Motoneurons were decreased myelin destruction Loss of axons <Mizuno J. et al, Neurol Res, 1992> MR imaging and pathological changes in our cervical chronic compression model is almost same changes as seen human in patients with OPLL or OYL.

In this model, the polyethylene line cuts into the dorsal wall of the spinal canal following the growth of the spinal canal and vertebral body, and gradually compressed the spinal cord. After 12 months from surgery, spinal canal of CCS model rat was narrowed to 65%, and spinal cord was compressed to 74% of control rat. This model was unique because of the slow disease s course, the lack of surgical damage in spinal epidural tissues or direct damage to spinal cord. Additionally, behavioral assessment was helpful and meaningful to accurately know specific functions of spinal cord. In our model, rats with polyethylene line presented motor deficits and sensory disturbances 12 months after surgery, however no clinical manifestation took place until 6 months after surgery. This insidious and delayed onset of symptoms is one of the most typical characteristics of chronic compression of spinal cord. CONCLUSION Our findings indicated that the decreased in the number of motoneurons preceded the onset of the disturbances of motor and sensory function. And our model well reproduced chronic compression of cervical cord in human. REFERENCES: 1) Shinomiya K, et al. Spine 17, S383, 1992. 2) Hoshino Y, et al. Clin Neurophysiol 110, 305, 1999. 3) Manabe S, et al. Spine 14, 1308, 1989. 4) Kim P, et al. Ann Neurol 55, 503, 2004. 5) Yamazaki M, et al.calcif Tissue Int 48, 182, 1991.